The Homing Of Autoreactive T Cells And Infiltration Of Inflammatory Cells

Sep 05, 2022

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Experimental autoimmune uveitis(EAU)is an animal model of human autoimmune uveitis that is characterized by the infiltration of autoimmune T cells with concurrent increases in pro-inflammatory cytokines and reactive oxygen species. This study aimed to assess whether betaine regulates the progression of EAU in Lewis rats. EAU was induced via immunization with the interphotoreceptor retinoid-binding protein (IRBP)and oral administration of either a vehicle or betaine(100 mg/kg) for 9 consecutive days. Spleens, blood, and retinas were sampled from the experimental rats at the time of sacrifice and used for the T cell proliferation assay, serological analysis, real-time polymerase chain reaction, and immunohistochemistry. The T cell proliferation assay revealed that betaine had little effect on the proliferation of splenic T cells against the IRBP antigen in an in vitro assay on day 9 post-immunization. The serological analysis showed that the level of serum superoxide dismutase increased in the betaine-treated group compared with that in the vehicle-treated group. cistanche tubulosa extract The anti-inflammatory effect of betaine was confirmed by the downregulation of pro-inflammation-related molecules, including vascular cell adhesion molecule I and interleukin-1 in in the retinas of rats with EAU. The histopathological findings agreed with those of ionized calcium-binding adaptor molecule l immunohistochemistry, further verifying that inflammation in the retina and ciliary bodies were significantly suppressed in the betaine-treated group compared with the vehicle-treated group. Results of the present study suggest that betaine is involved in mitigating EAU through anti-oxidation and anti-inflammatory activities.

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Key words:Anti-inflammation,Anti-oxidation,Betaine,Experimental autoimmune uveitis,Retina

Introduction

The homing of autoreactive T cells and infiltration of inflammatory cells, such as monocytes, trigger uveitis and retinitis in EAU [6]. The retina is damaged from inflammation with the activation of glial cells that undergoes oxidative stress[7].

Betaine, also called trimethylglycine (CH: NO:), is an alkaloid and nontoxic natural substance from Fructus Lycia, and a representative antioxidant substance [8]. Betaine improves age-related inflammation in rats through nuclear factor-kB involvement via nuclear factor-inducing kinase/I kappa B kinase and mitogen-activated protein kinases [9], human cardiovascular disease by suppressing inflammatory cytokines, including interleukin (IL)-6 and tumor necrosis factor-a(TNF-a)[10], and dextran sulfate sodium-induced colon tumorigenesis [11]. cistanche tubulosa reviews, In addition, betaine prevented pathological angiogenesis/neovascularization in rats with diabetic retinitis [12] and protected retinal ganglion cells to increase visual acuity in an animal model of glaucoma [13]. However, there is little known about the precise mechanisms underlying the effects of betaine in uveitis.

In this study, the efficacy of betaine in relieving EAU was evaluated. We investigated the anti-inflammatory effect of betaine in EAU based on histopathological examination and cytokine measurements. Furthermore, the specific mechanism of betaine as an antioxidant was assessed in rats with EAU.

MATERIALS AND METHODS

Animals

Both sexes of Lewis rats(7~9 weeks old; Orient Bio Inc, Gyeonggi-do, Korea) were housed in our facility under laboratory conditions (12-h light/dark cycle, temperature 23±2 degree ). All experimental procedures were performed following the Guidelines for the Care and Use of Laboratory Animals of Jeju National University (permission number:2020-0012). All animal protocols conformed to international laws and NIH policies, including the Care and Use of Laboratory Animals(NIH publication no.85-23,1985, revised 1996).

Induction of EAU

The rats were immunized with 200 ul of a mixed emulsion composed of an equal volume of bovine interphotoreceptor retinoid-binding protein (IRBP)(I mg/ml; PTARSVGAADGSS-WEGVGVVPDV, Komabiotech, Seoul, Republic of Korea) and Freund's complete adjuvant (CFA)supplemented with me mg/mL Mycobacterium tuberculosis H37Ra(Difco Laboratories Inc., Detroit, MI, USA)on the footpads of their hind limbs.

Experimental groups

To assess the effects of betaine(Fig.1A) on EAU, four experimental groups were designated as follows: normal control (n=8); CFA control (n=8);EAU plus Vehicle (n=8);and EAU plus Betaine(n=8).The dose in the treatment to test the therapeutic effect of betaine(10 mg/kg body weight/day, B2629, Sigma-Aldrich, St.Louis, MO, USA) was selected based on a previous study [14]. The rats were orally treated 9 with betaine from day 0 post-immunization until day 9 post-immunization.

Tissue preparation

The rats were sacrificed under deep anesthesia via CO2 gas inhalation on day 9 post-immunization. cistanche UK The tissues for the histopathological examination were embedded in paraffin wax and sectioned


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with a microtome (RM 2135; Leica, Nussloch, Germany) to a thickness of 5 um and stained with hematoxylin and eosin. Blood and retinas were stored at -80 degree for the serum analysis and real-time polymerase chain reaction(PCR)analysis.

T cell proliferation assay

Spleen mononuclear cells from the animals in each group were dissociated and suspended as described in our previous study [15]. Then,10 ug/ml IRBP (final concentration)was added to the wells. After 48 h of stimulation with IRBP, the cells were incubated in 1 μCi of 'H-methyl thymidine (specific activity 42 Ci/mmol; Amersham, Arlington Heights, IL, USA) for 18 h. Then, the cells were harvested to measure thymidine incorporation.

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Serological analysis

The rats were sacrificed on the sampling date, and blood was collected through the heart. Whole-blood samples were separated into serum and blood cells using a centrifuge (VS-5500CFN; Vision Scientific, Daejeon, Republic of Korea). Superoxide dismutase(SOD)activity in the serum was evaluated using a SOD kit (ab65354; Abcam, Cambridge, UK).

Immunohistochemistry

Immunohistochemistry was performed using the same protocol as that described in our previous study [16].The primary antibod-ies including ionized calcium-binding adapter moleculel (Ibal)(1:1,000;019-19741,Wako Pure Chemical Industries,Ltd,Osaka, Japan),CD68(ED1;1:800;MCA341,Serotec,Kidlington,UK), and glutamine synthetase(GS)(1:5,000;MAB302,Chemicon In-ternational, Temecula, CA,USA) were used as marker for microg-lia,macrophage and Müller cell,respectively.

Real-time PCR

Total RNA in the eyeballs in all groups (n=5 per group)was isolated with TRIzol RNA Isolation Reagent (Life Technologies, Thermo Fisher Scientific, Carlsbad, CA, USA), and cDNA was prepared using CellScript M All-in-One 5X First Standard cDNA Synthesis Master Mix(CellSafe, Gyeonggi-do, Republic of Korea). The primer information is listed in Table 1. PCR was performed with a MIC cycler(BMS, Queensland, Australia)using 2x SYBR Green (PhileKorea, Seoul, Republic of Korea) and the following program: 55 cycles of denaturation(5 s,95 degree ), annealing(20 s, 60 degree ), and extension(10s,72 degree ).

Western blot analysis

Western blot analysis was performed by the same protocol as that described in our previous study [16].cistanche wirkung The primary antibodies including Kelch-like ECH-associated protein 1 (Keap1)(1:1,000;abl19403,abcam,MA,USA),and Nuclear factor erythroid-2-re-lated factor2(Nrf2)(1:1,000;sc-722,Santa cruz,CA,USA).

Statistical analysis

All measurements are reported as the average of three independent experiments. All values are presented as the mean standard error of the mean (SEM). The results were analyzed using a one-way analysis of variance followed by the Student-Newman-Keuls posthoc test for multiple comparisons. A p-value<0.05 was="" considered="" to="" indicate="" significance.="" immunostaining="" was="" analyzed="" semi-quantitatively="" based="" on="" the="" positive="" areas="" in="" the="" photographs="" using="" imagej="" software="" (national="" institutes="" of="" health,="" bethesda,="" md,="" usa).eau="" was="" histopathologically="" evaluated="" using="" a="" method="" modified="" from="" a="" previous="" study="" [17].="" antibody-positive="" areas="" were="" measured="" as="" follows:(1)three="" different="" sections="" from="" each="" rat="" (n="3" animals="" per="" group)="" were="" used;="" then,="" (2)="" the="" percentage="" of="" the="" stained="" area="" [(positive="" area/total="" area)x100(%)]="" was="" calculated.="" the="" total="" area="" included="" all="" layers="" of="" the="" retina.="" these="" results="" are="" presented="" as="" the="">

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RESULTS

Betaine had no immunomodulatory function in EAU The T cell proliferation assay was performed to determine whether betaine affected the proliferation of IRBP-specific T cells (Fig.1B). No significant changes were observed between the EAU-induced groups in medium only and those that were IRBP-stim-ulated (medium only, p>0.05 vs.EAU+Vehicle; IRBP stimulation, p>0.05 vs.EAU plus Vehicle). These data indicate that betaine was not involved with IRBP-specific T cells or their auto-reactivity.

Betaine upregulated serum SOD levels in EAU

We evaluated oxidative damage in the serum, using SOD as a marker of oxidative modification. No significant difference was observed between the normal and CFA groups. SOD activity decreased significantly in the EAU plus Vehicle group, compared to levels in the normal control and CFA groups. Betaine treatment significantly restored the level of SOD activity to that of the normal control and CFA groups(Fig. 2). This result indicates that the betaine treatment suppressed oxidative stress in rats with EAU.

Betaine reduced the infiltration of Ibal-positive cells in the ciliary bodies and retinas of EAU-induced rats

The ciliary body is the main inflammatory cell infiltration site because of the abundance of blood vessels[18]. Only a few round-type cells were detected in the ciliary bodies in the normal and CFA groups (Fig. 3A,3B), whereas the infiltration of some round-type cells was confirmed in the EAU-induced groups (arrows in Fig.3C,3D). The normal (Fig.3E)and CFA(Fig.3F)groups consistently displayed similar results to those observed for Ibal immunoreactivity. Ibal-positive immunoreactivity increased in the EAU plus Vehicle and EAU plus Betaine groups (arrowheads in Fig.3G, 3H). However, the number of Ibal-positive cells decreased signifi-cantly in the EAU plus Betaine group compared to the EAU plus Vehicle group (Fig. 3I). We also analyzed the localization of EDI as a further approach to evaluate the precise location of inflammatory cell infiltration in the ciliary body.ED1-positive cells were rarely detected in the normal (Fig. 3G) and CFA (Fig. 3K)groups. By contrast, numerous ED1-positive cells were detected in the EAU plus Vehicle and EAU plus Betaine groups (double arrowheads in Fig.3L,3M). citrus bioflavonoids A semi-quantitative analysis of the number of ED1-positive cells confirmed that the betaine treatment suppressed the infiltration of inflammatory cells in the ciliary bodies of EAU-induced rats.

Next, we investigated histopathological changes in the retina (Fig. 4). A few inflammatory cells were detected in retinas with EAU, but not in normal and CFA rat retinas (Fig.4A~4D). The lesions were scored histopathologically according to the severity of EAU [17], revealing relief of retinal inflammation (Fig.4E). Microglial and Müller cell activation indicating retinal inflammation were confirmed based on global (Fig.4F~4I) and GS immunoreactivity (Fig.4K~4N), respectively. The localization of Ibal in microglia was very rare in the normal and CFA groups (arrowheads in Fig. 4F,4G, respectively). The activation of microglia was inhibited in EAU rats (arrowheads in Fig.4H) by the betaine treatment(Fig.4I, 4J). The GS-positive immunoreactivity result was similar to that of global in the retina (Fig.4K~4N). Activated Müller cells in the EAU plus Vehicle group had lower GS-immunoreactivity levels (Fig. 40).

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Betaine suppressed adhesion molecule and pro-inflammatory mediators in EAU

Next, we examined adhesion molecule expression using real-time PCR (Fig. 5A). A sharp decrease in the vascular cell adhesion molecule 1(VCAM1)mRNA level in the EAU plus Betaine group was observed (p<0.05 vs.eau+vehicle).="" the="" mrna="" levels="" of="" serpina3n,interleukin-1β(il-1β),="" tumor="" necrosis="" factor-alpha="" (tnf-a),="" inducible="" nitric="" oxide="" synthase(inos),="" and="" cyclooxygenase="" at-2(cox-2)as="" pro-inflammatory="" mediators,="" were="" assessed="" to="" confirm="" the="" inflammatory="" condition="" (fig.="" 5b).="" the="" mrna="" levels="" of="" serpina3n,="" il-1β,="" tnf-a,="" cox-2="" were="" significantly="" downregulated="" in="" the="" eau+betaine="" group="" compared="" with="" that="" of="" vehicle-treated="" eau="" group="" (fig.5b).="" these="" results="" indicate="" that="" the="" betaine="" treatment="" suppressed="" the="" upregulation="" of="" pro-inflammatory="">

Betaine upregulated the antioxidant enzymes catalase (CAT)andSODinEAU

The study of oxidative damage levels in the serum prompted us to investigate the antioxidant response status of antioxidant enzymes, including CAT, SOD1, SOD2, and SOD3(Fig.5C). We observed significantly upregulated expression levels of CAT, SOD1, SOD2, and SOD3 in the eyeballs of the EAU plus Betaine group com-pared with the EAU plus Vehicle group.

Betaine activated the Keapl-Nrf2 pathway

To support the anti-oxidative effect of betaine, the Keapl-Nrf2 pathway was examined (Fig. 6). The protein levels of Keapl (0.75±0.05 fold changes,p<0.05,fig.6a)and nrf2(0.79±0.04fold=""><0.05,fig.6b)in eau+vehicle="" group="" were="">

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compared with the normal control. On the other hand, the Keapl and Nrf2 showed either 1.46±0.00 fold changes or 1.13±0.34 fold changes to those of the EAU plus Vehide group (p<0.01 and=""><0.001,>

DISCUSSION

This is the first study reporting that betaine mitigates the progression of EAU pathogenesis through anti-inflammatory and anti-oxidant effects, but not by suppressing T cell proliferation (Schematic illustration in Fig.7).

The regulatory effect of betaine in autoimmune diseases as evidenced using EAU, a prototype of autoimmune disease, is thought to be due to the reduction of oxidative stress and pro-inflammatory mediators, but not T cell proliferation, by betaine [19]. Similarly, the present study revealed that betaine had little effect on T cell proliferation and the cytokine profile in the culture supernatant in an EAU model, suggesting that betaine does not influence the immune response of proliferation of autoimmune T cells in EAU. The uvea is a target organ in EAU. The uvea and retina are immunologically isolated organs without lymphatics [20]. The autoimmune T cells in EAU are invaded via a branch of the ciliary and ophthalmic arteries [21]. Oxidative stress is critical signaling to the progression of inflammatory response and the increased reactive oxygen species causes endothelial dysfunction and tissue injury [22]. The disturbed endothelial cells lead to the promotion of passage of inflammatory cells and inflammatory molecules [22]. Inflammatory mediators and cells in the uvea are triggered in the retinal pigment epithelial cells, which disturb the junctions between rod and cone cells and pigmented epithelial cells, leading to a detached retina [23]. The ciliary body is an entry site for ocular inflammation. Typical retinal inflammation is involved in the activation of resident microglia and the infiltration of inflammatory cells because of the breakdown of the blood-retina barrier [24]. Under the neuropathological conditions, including brain tumors [25], axotomy [26], and virus infection [27], the activated macrophages and microglia were distinguished by Ibal. In addition, activated resident microglia are involved in the pathological changes occurring in retinal degenerative diseases and release inflammatory mediators that exacerbate the disease process [28]. These results suggest that betaine exerts anti-inflammatory effects in the uvea and ciliary body, the main targets of EAU, and may reduce oxidative stress in the serum. However, the precise mechanism remains to be studied.

Activated microglia are the main source of pro-inflammatory cytokines under retinal degenerative conditions [29]. Pro-inflammatory cytokines, including ILs and TNF, are strongly associated with ocular inflammation [30] and retinitis[6,29]. Besides the microglia, Müller cells are activated under all pathological events that occur in the retina [31]. Activated Müller cells are involved in the neuroinflammatory effect in the retina by synthesizing and releasing inflammation-related molecules [31]. We postulate that betaine mitigates the inflammatory response in EAU-induced rats by suppressing the activation of microglia and Müller cells. The upregulation of VCAMl is highly involved in the infiltration of inflammatory cells [32].VCAMl is expedited to CD4 Tlym-phagocytes through cross-talk with late antigen-4[3].In addition, Serpina3n, an enzyme that initiates inflammation [34], has been detected in Müller cells, astrocytes, and retinal pigment epithelia of light-damaged retinas [35] and has significantly variable levels in the Nrl'mouse retina with impaired cone cells [36].Serpina3n is increased in EAU rats with severe retinal inflammation but decreased significantly in the betaine-treated EAU group. A similar finding has been reported for schizophrenia with neuroinflammation [34], as murine Serpina3n is an orthologue of human Serpina3 [37]. Furthermore, an increase in IL-1 was observed in high fructose-induced retinal injury [38]. We postulate that the anti-inflammatory effect of betaine is associated with the down-regulation of VCAM1, Serpina3n, and IL-1 in EAU-induced rats. The Keep-Nrf2 pathway is used to monitor oxidative stress [39]. Betaine had known as an anti-oxidant molecule, which was associated with the Keapl-Nrf2 pathway in the acetaminophen-induced acute liver injury model [40]. Additionally, the hepatic gene expression profiling was performed after the 3H-1,2-dithiole-3-thione treatment, having the role of enhancing the detoxification of carcinogens and protecting against neoplasia [4]. The result of this profiling revealed that the Keap1-Nrf2 regulated nrf2-dependent 3H-1,2-dithiole-3-thione-inducible gene, including AF033381, as betaine homocysteine methyl transferase, was increased, and involved to the detoxification and anti-oxidation [41]. The inflammatory response in EAU was induced by infiltration of inflammatory cells, such as T cells and macrophages [42], and production of oxidative stress, especially in photoreceptor mitochondria of early stage [43]. According to these results, the betaine treatment was a candidate to relieve the EAU-induced tissue damage by modulation of the Keap1-Nrf2 pathway, as a key pathway to regulation of oxidative stress.

The antioxidant effect of betaine has been widely evaluated in radical-induced injury models [44].In the levodopa-induced oxidative-damage brain, betaine was enhanced to the levels of CAT and SOD, which are representative antioxidant enzymes[4]. SOD1, SOD2, and SOD3 are activated by different mechanisms and are localized in the cytoplasm, mitochondria, and extracellular matrix, respectively [45]. Betaine, as an anti-oxidative molecule, is involved in reducing oxidative damage [46]. The reduced oxidative stress was extended to resolving the inflammation, indicated by Ibal-positive macrophages/microglia in many diseases, including Alzheimer's disease, Parkinson's disease, and multiple sclerosis [47]. The betaine treatment was upregulated to the mRNA levels of oxidative stress marker, compared with those in the EAU plus Vehicle group. This result implies that the betaine treatment reduced oxidative stress in the circulatory system without interfering with T cell proliferation in the immune organs of the rat EAU model.

Collectively, the present study suggests that betaine can mitigate inflammation in the retinas and ciliary bodies of EAU-induced rats, possibly through anti-oxidation and anti-inflammation mechanisms.


This article is extracted from https://doi.org/10.5607/en21011
















































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